CN119300329B - Radar load liquid cooling system - Google Patents

Abstract

The invention discloses a radar load liquid cooling system, which relates to the technical field of liquid cooling sources and comprises a rack, wherein one side of the rack is fixedly connected with a back plate, one side of the back plate is fixedly connected with an electric control box, and the electric control box is electrically connected with a temperature sensor. According to the invention, the water inlet and the water outlet of the water pump II are respectively connected with the transverse pipe and the L-shaped pipe, the medium in the evaporator can be discharged and sent into the auxiliary box, the medium flowing between the cooling mechanism I and the cooling mechanism II is different and is cooling water and glycol-type cooling liquid respectively, the temperature sensor is used for detecting the ambient temperature and switching between the cooling mechanism I and the cooling mechanism II, and the cooling is performed by using different mediums, so that the cooling effect of the radar can be ensured, the applicability of the device is further improved, the cooling liquid is distilled, the separation of glycol and cooling water is assisted, and the cooling water is collected into the collecting hopper I, so that the subsequent recycling of the cooling water is facilitated.

Description

Radar load liquid cooling system

Technical Field

The invention relates to the technical field of liquid cooling sources, in particular to a radar load liquid cooling system.

Background

Liquid cooling refers to a technique that uses a liquid as a cooling medium to remove heat. This technique transfers heat generated by the radar load to a radiator or other heat dissipating unit through the flow of liquid, which in turn discharges the heat to the environment to ensure that the radar system remains at a lower temperature during operation.

As chinese patent CN116546802a discloses a vehicle-mounted radar load liquid cooling source system, which comprises a machine body, the top of organism is erect and is installed the air inlet subassembly, the inside of organism is erect the fastening and is installed the regulation and control subassembly, the regulation and control subassembly includes the liquid reserve tank, the top of liquid reserve tank is four-port through the inflation screw group fastening and is installed the installation and connect the roof, the bottom intercommunication of liquid reserve tank is provided with closed cavity, the bottom of closed cavity sets up and installs the gas receiver, the central shaft face fixed mounting of closed cavity has the pole setting post, the internally mounted of gas receiver is provided with the shutoff valve plate, the outer wall week side surface of pole setting post is installed with three group's fishplates in equal parts about the fastening.

In the above patent, although the problem that the coolant cannot be actively regulated and controlled is solved through the regulating and controlling component, the medium inside the device is single, the heat conduction performance and specific heat capacity of the single medium are the same, the optimal cooling effect cannot be realized under different working environments and radar working loads, and the applicability of the whole device is reduced.

Disclosure of Invention

The invention aims to provide a radar load liquid cooling system, which aims to solve the problems that the medium in the device provided by the background art is single, the heat conduction performance and specific heat capacity of the single medium are the same, the optimal cooling effect can not be realized under different working environments and radar working loads, and the applicability of the whole device is reduced.

The radar load liquid cooling system comprises a rack, wherein one side of the rack is fixedly connected with a back plate, one side of the back plate is fixedly connected with an electric cabinet, one side of the electric cabinet is electrically connected with a temperature sensor, one side of the temperature sensor is fixedly connected with the back plate, one side of the temperature sensor is provided with a first cooling mechanism and a second cooling mechanism, one side of the rack is fixedly connected with a bottom plate, and the top of the bottom plate is provided with an auxiliary mechanism;

The auxiliary mechanism comprises an auxiliary box, a condensing cylinder and a distiller, wherein the bottom of the auxiliary box is fixedly connected with a bottom plate, a first collecting hopper and a second collecting hopper are fixedly connected to one side of the inner wall of the auxiliary box, a first supporting pipe and a second supporting pipe are fixedly connected to the bottom of the first collecting hopper and the bottom of the second collecting hopper respectively, a branch pipe is fixedly connected to one side of the second supporting pipe, the bottom of the branch pipe penetrates through the side wall of the top of the distiller, the bottom of the distiller is fixedly connected with the bottom of the inner cavity of the auxiliary box, a distilling pipe is fixedly connected to the top of the distiller, a coil pipe is fixedly connected to one end of the distilling pipe, a filter plate is lapped at the bottom of the coil pipe, the outer ring surface of the filter plate is connected with the inner wall of the condensing cylinder in a clamping manner, and a filter element is clamped on the inner wall of the condensing cylinder.

Preferably, the outer ring surface fixedly connected with cooling cover of condensation section of thick bamboo, the liquid storage chamber has been seted up to cooling cover inside, cooling cover top fixedly connected with inlet, cooling cover bottom fixedly connected with auxiliary frame, auxiliary frame bottom and auxiliary box fixed connection.

Preferably, the bottom of the condensation cylinder is penetrated and penetrated with a second connecting pipe, one end of the second connecting pipe is fixedly communicated with a first water pump, the bottom of the first water pump is fixedly connected with the auxiliary box, the top of the first water pump is fixedly communicated with a first connecting pipe, and one side of the first connecting pipe is fixedly communicated with the first collecting hopper.

Preferably, the auxiliary pipes are fixedly communicated with one side of the first support pipe and one side of the second support pipe, the three-way valve is fixedly communicated with one end of the auxiliary pipe, the guide pipe is fixedly communicated with one side of the three-way valve, one end of the guide pipe penetrates through the side wall of the auxiliary mechanism, the guide pipe is fixedly connected with the shunt pipe, and one end of the shunt pipe is fixedly communicated with the evaporator.

Preferably, one side of the auxiliary box is penetrated and penetrated with an L-shaped pipe, one end of the L-shaped pipe is fixedly communicated with a second water pump, the bottom of the second water pump is fixedly connected with the bottom plate, and one side of the second water pump is fixedly communicated with a transverse pipe.

Preferably, the bottom plate top and cooler bin fixed connection, cooler bin inner wall one side fixedly connected with support frame, support frame top and evaporimeter fixed connection, evaporimeter one side and lateral tube fixed communication.

Preferably, the second cooling mechanism has the same structure as the first cooling mechanism, a transverse plate is arranged between the second cooling mechanism and the first cooling mechanism, and one side of the transverse plate is fixedly connected with the back plate.

Preferably, the second cooling mechanism comprises a liquid storage cylinder, a condenser and an expansion valve, wherein the bottom of the liquid storage cylinder is fixedly connected with a transverse plate, one side of the liquid storage cylinder is fixedly communicated with a compressor, the bottom of the compressor is fixedly connected with the transverse plate, one side of the compressor is fixedly communicated with the condenser, and the bottom of the condenser is fixedly connected with the transverse plate.

Preferably, a fan is fixedly connected to one side of the condenser, one side of the condenser is fixedly communicated with the liquid storage cylinder, a filter is fixedly communicated to one side of the liquid storage cylinder, and the bottom of the filter is fixedly connected with the transverse plate.

Preferably, the filter one end fixed intercommunication has the extension pipe, the expansion valve is installed to extension pipe one end, expansion valve one end and the fixed intercommunication of evaporimeter, the fixed intercommunication in evaporimeter top has the condenser pipe, condenser pipe one end and compressor one side fixed intercommunication.

Compared with the prior art, the invention has the beneficial effects that:

1. According to the radar cooling device, the water inlet and the water outlet of the water pump II are respectively connected with the transverse pipe and the L-shaped pipe, medium in the evaporator can be discharged and sent into the auxiliary box, the medium flowing between the cooling mechanism I and the cooling mechanism II is different and is cooling water and glycol type cooling liquid respectively, the temperature sensor is used for detecting the switching between the ambient temperature and the cooling mechanism I and the cooling mechanism II, and the cooling effect of the radar can be guaranteed by using different mediums for cooling, so that the applicability of the radar cooling device is improved.

2. According to the invention, one end of the branch pipe is fixedly communicated with the second support pipe, the circulation direction of the glycol-type cooling liquid can be changed through the second support pipe and the branch pipe, the glycol-type cooling liquid can be sent into the distiller through the branch pipe, and the cooling liquid is distilled, so that the separation of glycol and cooling water is assisted, the cooling water is collected into the first collecting hopper, the subsequent recycling of the cooling water is facilitated, and the resource utilization rate of a medium is improved.

3. In the invention, the cooling sleeve is arranged outside the condensing cylinder, the coil pipe is arranged inside the condensing cylinder, the cooling sleeve can be used for cooling the outside of the condensing cylinder in an auxiliary way, and the temperature of distilled water in the condensing cylinder is reduced, so that the distilled water can be conveniently collected, and the filter plate and the filter element can be used for filtering and purifying the distilled water, thereby avoiding the blockage generated during the recovery of the distilled water and ensuring the smooth recovery of the distilled water.

Drawings

FIG. 1 is a schematic diagram of a three-dimensional structure of a radar load liquid cooling system according to the present invention;

FIG. 2 is a schematic diagram illustrating the installation of a liquid storage tank and a compressor of a radar load liquid cooling system according to the present invention;

FIG. 3 is a schematic diagram of the internal structure of a cooling tank of the radar load liquid cooling system according to the present invention;

FIG. 4 is a schematic diagram illustrating the installation of a collecting bucket of the radar load liquid cooling system according to the present invention;

FIG. 5 is a schematic diagram illustrating a support tube structure of a radar load liquid cooling system according to the present invention;

FIG. 6 is a schematic diagram illustrating the structural installation of a distiller of a radar load liquid cooling system according to the present invention;

FIG. 7 is a schematic diagram showing the structural connection between a branch pipe of a radar load liquid cooling system and a distiller;

FIG. 8 is a schematic diagram showing the installation of a filter plate structure of a radar load liquid cooling system according to the present invention.

In the figure:

1. The device comprises a rack, 2, an auxiliary mechanism, 21, an auxiliary tank, 22, a first collecting hopper, 221, a first supporting pipe, 23, a condensing cylinder, 231, a coil, 232, a filter plate, 233, a filter core, 24, a first water pump, 241, a first connecting pipe, 242, a second connecting pipe, 25, an auxiliary pipe, 26, a three-way valve, 27, a cooling jacket, 28, a second collecting hopper, 281, a second supporting pipe, 29, a distiller, 291, a distillation pipe, 292, a branch pipe, 3, a bottom plate, 4, a cooling tank, 41, an evaporator, 42, a supporting frame, 43, a guide pipe, 5, a first cooling mechanism, 6, an electric control tank, 61, a back plate, 7, a temperature sensor, 8, a second cooling mechanism, 81, a liquid storage cylinder, 82, a compressor, 83, a condenser, 84, a condensing pipe, 85, an expansion valve, 86, a filter, 87, a fan, 88, a cross plate, 9, a second water pump, 91, an L-shaped pipe, 92 and a transverse pipe.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-8, the radar load liquid cooling system comprises a rack 1, a back plate 61 is fixedly connected to one side of the rack 1, an electric cabinet 6 is fixedly connected to one side of the back plate 61, a temperature sensor 7 is electrically connected to the electric cabinet 6, one side of the temperature sensor 7 is fixedly connected to the back plate 61, a first cooling mechanism 5 and a second cooling mechanism 8 are arranged on one side of the temperature sensor 7, a bottom plate 3 is fixedly connected to one side of the rack 1, an auxiliary mechanism 2 is mounted on the top of the bottom plate 3, the auxiliary mechanism 2 comprises an auxiliary box 21, a condensing cylinder 23 and a distiller 29, the bottom of the auxiliary box 21 is fixedly connected with the bottom plate 3, a first collecting hopper 22 and a second collecting hopper 28 are fixedly connected to one side of an inner wall of the auxiliary box 21, a first supporting pipe 221 and a second supporting pipe 281 are fixedly connected to the bottom of the first collecting hopper 22 and the second collecting hopper 28 respectively, a branch pipe 292 is fixedly connected to one side of the supporting pipe 292, the bottom of the branch pipe 292 penetrates through the top side wall of the distiller 29, the bottom of the distiller 29 is fixedly connected to the bottom of an inner cavity of the auxiliary box 21, a distilling pipe 291 is fixedly connected to the top, a lap joint 231 is fixedly connected to one end of the distiller 29, a filter plate 231 is fixedly connected to the inner wall of the distiller 232, and the inner wall of the condenser 23 is fixedly connected to the inner wall of the filter plate 232.

The outer ring surface fixedly connected with cooling cover 27 of condensation section of thick bamboo 23, the liquid storage chamber has been seted up to cooling cover 27 inside, cooling cover 27 top fixedly connected with inlet, cooling cover 27 bottom fixedly connected with auxiliary frame, auxiliary frame bottom and auxiliary tank 21 fixedly connected, the penetration in condensation section of thick bamboo 23 bottom is equipped with connecting pipe two 242, connecting pipe two 242 one end fixedly communicates there is water pump one 24, water pump one 24 bottom and auxiliary tank 21 fixedly connected, water pump one 24 top fixedly communicates there is connecting pipe one 241, connecting pipe one 241 side and collecting hopper one 22 fixedly communicate.

In this embodiment, the electric cabinet 6 is used to assist in switching and controlling the use of the cooling mechanism two 8 or the cooling mechanism one 5, the temperature sensor 7 can detect the ambient temperature of the current system operation, thereby assisting in judging the use of the cooling mechanism two 8 or the cooling mechanism one 5, the back plate 61 can provide support for the electric cabinet 6 and the temperature sensor 7, the installation of the temperature sensor 7 and the electric cabinet 6 on one side of the rack 1 is realized, the auxiliary box 21 can be used for wrapping and protecting the outer parts of the collecting hopper one 22 and the collecting hopper two 28, the valve is installed on the supporting tube one 221 and the supporting tube two 281, the medium contained in the collecting hopper one 22 and the collecting hopper two 28 can be discharged respectively by the supporting tube one 221 and the supporting tube two 281, wherein when the medium flows in the supporting tube one 221, the medium can be guided by the flow of the medium, the medium can be smoothly discharged into the distiller 29, the cooling sleeve 27 can accelerate the heat conduction of the outer surface of the distiller 29, thereby ensuring the condensation effect of the water vapor in the interior of the condensing cylinder 23, the auxiliary frame can be the cooling sleeve 27 and the bottom of the condensing cylinder 23, and the stability of the auxiliary frame can be used in the auxiliary box 21;

The distiller 29 is utilized to carry out distillation treatment, the distillation pipe 291 can guide steam generated by distillation in the distiller 29, the steam enters the coil 231, cooling condensation of the steam can be realized through the coil 231, distilled water is discharged from the coil 231, the distilled water can be preliminarily filtered by the filter plate 232, the distilled water and solid impurities are separated, the filtered distilled water can be adsorbed and purified by the filter element 233, the separation effect of glycol-type cooling liquid is improved, the quick recovery of the distilled water is further ensured, the second connecting pipe 242 can guide the distilled water to flow into the first water pump 24, the first connecting pipe 241 can assist the distilled water to enter the first collecting hopper 22 for collection, and the integral recovery of the distilled water is completed.

According to the second embodiment, as shown in fig. 1-5, an auxiliary pipe 25 is fixedly communicated with one side of each of a first support pipe 221 and a second support pipe 281, a three-way valve 26 is fixedly communicated with one end of the auxiliary pipe 25, a guide pipe 43 is fixedly communicated with one side of the three-way valve 26, one end of the guide pipe 43 penetrates through the side wall of the auxiliary mechanism 2, a shunt pipe is fixedly connected with one end of the guide pipe 43, an evaporator 41 is fixedly communicated with one end of the shunt pipe, an L-shaped pipe 91 is inserted into one side of the auxiliary tank 21, a water pump 9 is fixedly communicated with one end of the L-shaped pipe 91, the bottom of the water pump 9 is fixedly connected with a bottom plate 3, a transverse pipe 92 is fixedly communicated with one side of the water pump 9, the top of the bottom plate 3 is fixedly connected with the cooling tank 4, a support frame 42 is fixedly connected with one side of the inner wall of the cooling tank 4, the top of the support frame 42 is fixedly connected with the evaporator 41, one side of the evaporator 41 is fixedly communicated with the transverse pipe 92, the cooling mechanism 8 is identical to the cooling mechanism 5, a transverse plate 88 is arranged between the cooling mechanism 8 and the cooling mechanism 5, and the transverse plate 88 is fixedly connected with the back plate 61.

In this embodiment, the communication between the first support pipe 221 or the second support pipe 281 and the guide pipe 43 can be controlled by the three-way valve 26, so as to control different types of mediums to circulate inside the guide pipe 43, the medium can be recovered through the guide of the guide pipe 43, the second water pump 9 is connected with the L-shaped pipe 91 and the transverse pipe 92, the medium can be accelerated to flow between the evaporator 41 and the auxiliary tank 21, thereby improving the medium circulation speed, the integral liquid cooling effect is ensured, the bottom plate 3 can be used for providing support for the bottom of the second water pump 9, the stable use of the second water pump 9 is ensured, the cooling tank 4 can be used for wrapping and protecting the outside of the evaporator 41, the support frame 42 is fixedly connected with the inner wall of the cooling tank 4, the support frame 42 can be used for supporting and reinforcing the bottom of the evaporator 41, the cooling liquid is contained inside the cooling tank 4, the auxiliary evaporator 41 cools the equipment, the evaporation effect of the evaporator 41 is improved, the bottom of the cooling mechanism 8 can be supported by the transverse plate 88, and the separation of the second cooling mechanism 8 and the first cooling mechanism 5 is realized.

According to the third embodiment, as shown in fig. 1-3, the cooling mechanism II 8 comprises a liquid storage cylinder 81, a condenser 83 and an expansion valve 85, wherein a transverse plate 88 is fixedly connected to the bottom of the liquid storage cylinder 81, a compressor 82 is fixedly connected to one side of the liquid storage cylinder 81, the bottom of the compressor 82 is fixedly connected with the transverse plate 88, the condenser 83 is fixedly connected to one side of the compressor 82, the bottom of the condenser 83 is fixedly connected with the transverse plate 88, a fan 87 is fixedly connected to one side of the condenser 83 and the liquid storage cylinder 81, a filter 86 is fixedly connected to one side of the liquid storage cylinder 81, the bottom of the filter 86 is fixedly connected with the transverse plate 88, an extension pipe is fixedly connected to one end of the filter 86, the expansion valve 85 is installed at one end of the extension pipe, one end of the expansion valve 85 is fixedly connected with the evaporator 41, a condensation pipe 84 is fixedly connected to the top of the evaporator 41, and one end of the condensation pipe 84 is fixedly connected with one side of the compressor 82.

In this embodiment, through the connection between the liquid storage cylinder 81 and the compressor 82, the flow of the medium can be realized, the bottom of the liquid storage cylinder 81 and the bottom of the compressor 82 can be stably supported by utilizing the transverse plate 88, so that the stability of the liquid storage cylinder 81 and the bottom of the compressor 82 during use can be improved, the liquid discharged by the liquid storage cylinder 81 can be filtered by the filter 86, thereby blocking caused by the flow of the liquid in a pipeline can be avoided, the flowing effect of the liquid can be ensured, the connection of the expansion valve 85 and the evaporator 41 can be realized through the extension pipe, the flowing of the liquid can be guided, the communication between the evaporator 41 and the compressor 82 can be realized by utilizing the compressor 82, and the compression of the gas and the liquid can be assisted, so that the operation of the whole cooling process can be assisted.

The use method and the working principle of the device are that firstly, gas in the evaporator 41 can enter the compressor 82, the gas enters the condenser 83 for condensation through the compressor 82, the condensed liquid enters the liquid storage cylinder 81 for storage, then the liquid enters the filter 86 and is sent into the evaporator 41 again through the expansion valve 85, cooling liquid is contained in the cooling box 4 and can cool the evaporator 41, medium flowing between the cooling mechanism I5 and the cooling mechanism II 8 is different, one medium is cooling water, the other medium is glycol-type cooling liquid, the cooling liquid in the evaporator 41 can be discharged through the transverse pipe 92, the liquid in the first collecting bucket 22 or the second collecting bucket 28 respectively through the corresponding water pump II 9, the liquid in the first collecting bucket 22 and the second collecting bucket 28 can enter the three-way valve 26 through the support pipe 221 and the support pipe II 281 respectively after being treated, and the liquid is conveyed into the cooling box 4 through the guide pipe 43, and circulation of the liquid is realized;

When the whole system is used, the temperature sensor 7 is used for detecting the external environment temperature, when the temperature is in a preset range, the temperature sensor 7 sends a signal to a PLC (programmable logic controller) inside the electric cabinet 6, after the electric cabinet 6 receives the signal, the cooling mechanism I5 is started, cooling water circulates in the cooling mechanism I5 to realize cooling treatment on a radar load, when the temperature sensor 7 detects that the external environment temperature is lower than the preset value, the cooling mechanism II 8 is started to enable glycol-type cooling liquid to circulate in the cooling mechanism II 8, when the cooling liquid is sent into the collecting hopper II 28 through the water pump II 9, the cooling liquid enters the three-way valve 26 through the supporting pipe II 281, and then enters the cooling box 4 connected with the collecting hopper II 28 through the guide pipe 43, so that the circulation of glycol-type cooling liquid is completed;

When the second cooling mechanism 8 is used, the second water pump 9 is used for sending the excessive glycol-type cooling liquid into the second collecting hopper 28, the valve on the second supporting pipe 281 is controlled to be opened, the cooling liquid is sent into the branch pipe 292 and then enters the distiller 29 to carry out distillation treatment on the cooling liquid, because the boiling points of glycol and water are different, when the water boils, the water vapor can enter the coil 231 through the distillation pipe 291, the glycol remains in the distiller 29, the water vapor is condensed through the coil 231 and then is discharged through the tail end of the coil 231, the water vapor is filtered by the filter plate 232 to remove solid particles and impurities in the water vapor, the distilled water moves and is filtered and adsorbed by the filter element 233, active carbon particles are arranged inside the filter element 233, organic solvents and pigments in the water can be adsorbed, the purified water is collected at the bottom of the inner cavity of the condenser 23 and contacts the inner wall of the condenser 23 to carry out cooling treatment, the temperature difference between distilled water and the condensation cylinder 23 is reduced, the condensation cylinder 23 is made of heat-conducting metal, water is contained in a liquid storage cavity of the cooling sleeve 27, when the cooling sleeve 27 exchanges heat with the outer surface of the condensation cylinder 23, the water in the liquid storage cavity absorbs heat, thereby accelerating the cooling of the condensation cylinder 23, realizing the surface heat dissipation of the condensation cylinder 23, keeping the low temperature of the condensation cylinder 23, further assisting a coil 231 in the condensation cylinder 23 to cool and condense the water, the top of the cooling sleeve 27 is provided with a liquid inlet, the bottom is provided with a liquid outlet, the water in the cooling sleeve 27 can be replaced, thereby ensuring the cooling effect of the cooling sleeve 27 on the condensation cylinder 23, accelerating the water flow by a water pump I24, enabling the water to enter the water pump I24 through a connecting pipe II 242, then being sent into a collecting hopper I22 through a connecting pipe I241, a one-way valve being arranged on the connecting pipe I241, preventing the water from flowing backwards, the water enters the first collecting hopper 22 and is collected with the cooling water in the first collecting hopper 22, so that distilled water can be recovered, and the utilization rate of glycol type cooling liquid is improved.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims (6)

1. A radar load liquid cooling system, comprising a rack (1), wherein one side of the rack (1) is fixedly connected to a back plate (61), characterized in that: one side of the back plate (61) is fixedly connected to an electric control box (6), the electric control box (6) is electrically connected to a temperature sensor (7), one side of the temperature sensor (7) is fixedly connected to the back plate (61), one side of the temperature sensor (7) is provided with a cooling mechanism 1 (5) and a cooling mechanism 2 (8), the cooling mechanism 2 (8) having the same structure as the cooling mechanism 1 (5), a transverse plate (88) is provided between the cooling mechanism 2 (8) and the cooling mechanism 1 (5), one side of the transverse plate (88) is fixedly connected to the back plate (61), the cooling mechanism 2 (8) comprises a liquid storage cylinder (81), a condenser (83) and an expansion valve (85), the bottom of the liquid storage cylinder (81) is fixedly connected to the transverse plate (88), one side of the liquid storage cylinder (81) is fixedly connected to a compressor (82), the bottom of the compressor (82) is connected to the transverse plate ( 88), one side of the compressor (82) is fixedly connected to a condenser (83), the bottom of the condenser (83) is fixedly connected to a transverse plate (88), one side of the condenser (83) is fixedly connected to a fan (87), one side of the condenser (83) is fixedly connected to a liquid storage cylinder (81), one side of the liquid storage cylinder (81) is fixedly connected to a filter (86), the bottom of the filter (86) is fixedly connected to the transverse plate (88), one end of the filter (86) is fixedly connected to an extension pipe, one end of the extension pipe is installed with an expansion valve (85), one end of the expansion valve (85) is fixedly connected to an evaporator (41), the top of the evaporator (41) is fixedly connected to a condensing pipe (84), one end of the condensing pipe (84) is fixedly connected to one side of the compressor (82), one side of the frame (1) is fixedly connected to a bottom plate (3), and the top of the bottom plate (3) is installed with an auxiliary mechanism (2); the cooling medium of the cooling mechanism 1 (5) and the cooling mechanism 2 (8) is different; The auxiliary mechanism (2) comprises an auxiliary box (21), a condensing cylinder (23) and a distiller (29); the bottom of the auxiliary box (21) is fixedly connected to the bottom plate (3); one side of the inner wall of the auxiliary box (21) is fixedly connected to a collecting bucket 1 (22) and a collecting bucket 2 (28); the bottoms of the collecting bucket 1 (22) and the collecting bucket 2 (28) are respectively fixedly connected to a supporting tube 1 (221) and a supporting tube 2 (281); one side of the supporting tube 2 (281) is fixedly connected to a branch pipe (292); the branch pipe The bottom of (292) penetrates the top side wall of the distiller (29); the bottom of the distiller (29) is fixedly connected to the bottom of the inner cavity of the auxiliary box (21); the top of the distiller (29) is fixedly connected to a distillation tube (291); one end of the distillation tube (291) is fixedly connected to a coil (231); a filter plate (232) is overlapped at the bottom of the coil (231); the outer annular surface of the filter plate (232) is snap-fitted to the inner wall of the condensation cylinder (23); and a filter element (233) is snap-fitted to the inner wall of the condensation cylinder (23). 2. A radar load liquid cooling system according to claim 1, characterized in that: a cooling sleeve (27) is fixedly connected to the outer ring surface of the condensing cylinder (23), a liquid storage cavity is opened inside the cooling sleeve (27), a liquid inlet is fixedly connected to the top of the cooling sleeve (27), an auxiliary frame is fixedly connected to the bottom of the cooling sleeve (27), and the bottom of the auxiliary frame is fixedly connected to the auxiliary box (21). 3. A radar load liquid cooling system according to claim 2, characterized in that: a connecting pipe 2 (242) is inserted through the bottom of the condensing cylinder (23), one end of the connecting pipe 2 (242) is fixedly connected to a water pump 1 (24), the bottom of the water pump 1 (24) is fixedly connected to the auxiliary box (21), the top of the water pump 1 (24) is fixedly connected to a connecting pipe 1 (241), and one side of the connecting pipe 1 (241) is fixedly connected to a collecting bucket 1 (22). 4. A radar load liquid cooling system according to claim 3, characterized in that: one side of the support tube 1 (221) and the support tube 2 (281) are both fixedly connected to an auxiliary tube (25), one end of the auxiliary tube (25) is fixedly connected to a three-way valve (26), one side of the three-way valve (26) is fixedly connected to a guide tube (43), one end of the guide tube (43) passes through a side wall of the auxiliary mechanism (2), and the guide tube (43) is fixedly connected to a shunt tube, and one end of the shunt tube is fixedly connected to an evaporator (41). 5. A radar load liquid cooling system according to claim 4, characterized in that: an L-shaped tube (91) is inserted through one side of the auxiliary box (21), one end of the L-shaped tube (91) is fixedly connected to a second water pump (9), the bottom of the second water pump (9) is fixedly connected to the bottom plate (3), and one side of the second water pump (9) is fixedly connected to a transverse tube (92). 6. A radar load liquid cooling system according to claim 5, characterized in that: the top of the base plate (3) is fixedly connected to the cooling box (4), a support frame (42) is fixedly connected to one side of the inner wall of the cooling box (4), the top of the support frame (42) is fixedly connected to the evaporator (41), and one side of the evaporator (41) is fixedly connected to the transverse pipe (92).